The DEA approach is chosen to avoid functional form specification error

Assessing the sustainability of agricultural systems is challenging because measurements frequently mix multiple dimensions, scales, and benchmarks. This study uses data envelopment analysis to develop benchmarks for comparing the sustainability of different agricultural systems and cropping techniques with a measure of sustainability called sustainable value . Incorporating DEA into the sustainable value approach expands upon the work of Figge and Hahn , who first introduced SV in the journal Ecological Economics. SV calculations integrate human, natural resource, and financial dimensions to generate a monetary measure of sustainability. The Loess Plateau provides a rich context to illustrate how sustainability measurements can be used to assess natural resource management trade-offs. It is a highly distressed region where intensive crop production is undermined by high soil erosion rates that threaten the long-term sustainability of the land and local food production . The Loess Plateau is one of the most severely degraded areas in the world, with over 60% of its land subjected to soil degradation and an average annual soil loss of 20–25 t/ha . Land use changes are often extreme. Much of the agricultural land has already been planted to trees through the Grain for Green program . However, converting from cropland to trees is an extreme conservation measure that generates little economic return to farmers who make a living mostly on their land. Many have migrated to urban areas in order to compensate for lost farm jobs, leading to other unintended consequences. In some cases child-care and other parental activities have been left to the elderly or older children . Rather than focusing on extreme land use changes,arándanos azules cultivo the analysis presented in this paper investigates how to balance environmental objectives with continued crop production.

Many frameworks have been proposed to measure sustainability. Macro scale proposals include the Green National Product , Ecological Footprints , and Genuine Savings . These methods are generally used to readjust Gross Domestic Product or Gross National Product calculations to account for net changes in environmental degradation. While ecologically minded organizations promulgate these alternative accounting approaches, the frameworks are not widely applied in China. Unlike the DEA/SV method proposed in this paper, these macro-level approaches do not explicitly map the value of meeting different environmental targets that are affected by local and regional agricultural production practices.SV is used to calculate net sustainable values, rather than the environmental burden imposed by natural resource use. First presented in Ecological Economics by Figge and Hahn , SV is based upon Capital Theory . SV assesses the sustainability of a proposed or existing system by comparing the opportunity cost of using capital in that system rather than a predetermined benchmark. SV can be used to evaluate the effectiveness of local or regional natural resource management decisions. For example, Van Passel et al. apply the SV approach to the Flemish dairy industry, finding the method to be useable and workable for smaller enterprises. Two years later the authors improved upon the method by applying a parametrically estimated efficiency frontier to provide individual benchmarks for each system . The research presented in this paper takes advantage of the SV approach to study cropping systems in the Loess Plateau, but refines it by creating discrete, customized individual benchmarks using a DEA. The DEA allows for comparison between similar systems and creates a discrete benchmark that is specifically comparable to that system. In contrast to previous studies that chose a single “best” benchmark, or a parametrically estimated frontier, the DEA method allows us to create a non-parametric frontier of benchmarks that takes into account the most efficient use of capital for each unique system .

The SV for over 2000 cropping systems reviewed for the Loess Plateau is recorded in a series of comparison matrices and organized by crop type, cropping technique or land type. These matrices are then used to determine which management practices, like rotation or terracing, have the greatest impact on sustainability. Although this would be the first known integration of the DEA with SV methods, the DEA method has been applied to other sustainability measures. For example, it has been used to compute environmental efficiency . Environmental efficiency is formulated in the same way as technical efficiency except that environmental impacts, rather than observed inputs, are calculated. One limit of environmental efficiency is that it becomes difficult to measure environmental impacts. Eco-efficiency, defined as the ratio of a created value over the environmental impact, is another popular indicator for measuring sustainability that used DEA . According to Van Passel et al. , the rebound effect is one major shortcoming of eco-efficiency. The rebound effect means that advances in environmental performance may be over stated because better eco-efficiency may also lead to growth and thus increase the use of environmental resources. The paper is organized, as follows: The methodology, presented in Section 2, updates Figge and Hahn’s SV approach by introducing frontier benchmarks estimated with DEA. Section 3 contains a description of the Loess Plateau study area and the simulation data, created from the Environmental Policy Integrated Climate model . This simulation is conducted on more than 2000 different cropping-system variations that are based upon Lu’s original work and a subsequent publication that uses approximately 500 of these cropping systems . The sustainability measurements evaluate different combinations of crop rotations, production situations, terracing techniques, tillage techniques, crop residue management techniques, mechanization levels, and land units. The empirical results are reported in Section 4. Discussion and conclusions are provided in Sections 5 and 6, respectively.This section provides a summary of steps for calculating SV and SE, which are applied to the Loess Plateau example.

According to Van Passel et al. , the SV and SE can be calculated in three steps. First, the scope of the analysis is determined. The data used in the presenting study employs 2006 distinct cropping systems as entities to create sustainable value. The entities all employ all three forms of capital. Different cropping systems are characterized by various technologies and practices such as crop rotations and terracing techniques. Second, relevant resources must be identified. In the context of sustainable development, the weight of relative importance of the capital forms used by a firm can be judged by the scarcity or degree of depletion of the capital . Over 60% of land in the Loess Plateau is subjected to soil degradation. Nitrogen loss is associated with soil loss. Thus, in this study soil and nitrogen are recognized as two forms of natural capital. Soil and nitrogen data are rare to observe at the farm level or national level, which strengthens the rationale for utilizing a SV measurement. Fortunately, the simulation model in Lu et al. , which is verified by experiments, provides extensive and realistic estimates of soil and nitrogen losses associated with various cropping practices. In addition to natural capital, financial capital and human capital are also taken into account through enterprise budgeting. Third, appropriate benchmarks must be determined. Four possible benchmarks were proposed by Van Passel et al. . First, the weighted average of a sample can be used. For example,maceta de 30 litros cropping systems with conservation practices can be chosen to calculate benchmarks. Second, a super-efficient firm that uses every single type of capital in the most efficient way can serve as the super-efficient benchmark. In practice, a super-efficient cropping system is highly unlikely. Third, a performance target can be used as a benchmark. A performance target example given by Van Passel et al. is 150 kg nitrogen per ha for the farm gate nitrogen surplus for dairy farms. Fourth, the unweighted average of all firms in the sample can be used as a benchmark.The benchmark choice reflects a normative judgment of sustainable development, and thus biases the way in which the SV is interpreted . Benchmarks should therefore be chosen with great care. Since the goal of this study is to identify the most sustainable cropping systems, the best performance benchmark is preferred. A performance target may also be appropriate, but it may not be easy to specify the reasonable target level. In this paper, many possible cropping systems for the Loess Plateau are considered, so a frontier is constructed for all the possible cropping systems. The frontier takes into account the most efficient use of capital for each unique system, rather than assuming that there is a single best system. Instead of using the parametric frontier benchmark proposed by Van Passel et al. , this study adopts a non-parametric DEA to determine benchmarks. Both parametric and non-parametric approaches have been proposed in the frontier literature . Data noise can be taken into account in the parametric approach, but specification error may arise from the choice of the functional form. The dataset incorporated in this study is simulated from the EPIC model, which is described in greater detail in Section 3.

Data noise is not expected to play a significant role in the estimation of the production frontier in this study because simulated data do not present sampling bias; that is, the simulated data can be readily replicated. The DEA method is also more computationally efficient, especially when multiple capital types are considered in the production process. Another advantage is that a unique frontier benchmark is specified for each cropping system through the consideration of each technology possibility. Lu et al. identified the cropping systems in Ansai County of the Loess Plateau. A summary of these systems is presented in Table 2. Their dataset includes 2006 cropping systems that are comprised of different combinations of 5 land units, 17 crop rotations, 3 production situations, 3 terracing techniques, 2 tillage techniques, 2 crop residue management techniques and 2 mechanization levels. Corresponding outputs of interest were simulated for each system using the Environmental Policy Integrated Climate model and validated with the experimental data as described by Lu et al. . EPIC is a comprehensive simulation model designed to predict the effects of management decisions on soil, water, nutrient and pesticide movements and their combined impact on soil loss, water quality and crop yield . It consists of weather, surface runoff, water and wind erosion, nitrogen leaching, pesticide fate and transport, crop growth and yield, crop rotations, tillage, plant environment control , economic accounting, and waste management. Lu et al. developed the comprehensive dataset regarding soil, weather, crop management, fertilizer and other parameters to meet the basic requirements to run the EPIC model. Hundreds of equations are applied in EPIC to then simulate processes such as crop growth and soil erosion. As described in Section 2, in order to apply the SV approach with DEA benchmarks, the value added and capital need to be specified. As previously defined, crop revenue minus intermediate consumption is specified as “value added” in the SV approach. To cope with multidimensionality, it is assumed that each cropping system uses all forms of capital to produce value. Typically, natural capital is difficult to measure. However, the EPIC model provides an opportunity to measure soil loss and nitrogen losses directly. Nitrogen losses are estimated in EPIC through “runoff and sediment, nutrient movement by soil evaporation, denitrification, ammonia nitrification and volatilization, mineralization, immobilization, biological-fixation, contribution of rainfall and irrigation, and NO3-N leaching Lu et al. .” Lu et al. note that most of the losses of N resulted from volatilization, runoff and soil erosion. Soil loss and nitrogen loss from the EPIC model are treated as natural capital inputs in the production process. Labor is viewed as human capital. Financial capital is calculated by aggregating all conventional inputs, including seeds, nutrients , biocides, irrigation if applicable, and farm equipment . Descriptive statistics of the data are given in Table 3. Revenue and cost data, except labor, are expressed in Chinese monetary units, the RMB. Natural capital, soil and nitrogen, are described in physical units. Financial capital and human capital are expressed in the RMB monetary units. On average, 5221 RMB/ha in revenue can be produced by a 3112 kg/ha soil loss and 15.3 kg/ha nitrogen loss, a cost of 1654 RMB/ha and 1390 RMB/ha for labor. Prices used to calculate aggregate value added and capital are taken from Lu et al. .

Water can be pumped during off peak hours and stored on a farm in many different ways

Operation of surface water pumps are limited by surface water availability and delivery schedules with little inherent flexibility. Dwindling surface water sources has made operation of surface water pumps even less flexible as they are dictated by water availability and not the irrigation schedule, energy cost, and/or the grid needs. The most convenient form of energy storage on a farm is not a battery or similar technology but is in the form of water storage.Soil moisture is the most common form of water storage on a farm. Adjusting the soil properties can significantly increase soil’s moisture uptake capacity. More recently, farmers in California have started a new form of water storage by flooding their fields even outside of the irrigation season. This will recharge the groundwater aquifers during times of year when excess surface water is available . Another form of water storage that can be beneficial for DR participation is above groundwater storage . On farm water storage can act equivalently as a battery, smoothing the electricity demand for irrigation. Availability of water storage allows irrigation when needed, or when it makes the most economical sense and not when water is available. The speed of an alternating current electric motor in a pump system is directly proportional to the frequency of the power supply. A Variable Frequency Drive6  takes the electrical supply from the utility and changes the frequency of the electric current,cultivo del arandano azul which results in a change of motor speed .

VFDs are most commonly installed for energy saving purposes; however, improved process control is another reason for installing VFDs. VFDs, although promising for AutoDR can pose potential disadvantages such as damage to the motor bearing and other components if operated improperly. Considerations must also be given to VFD reliability, maintenance costs, and skills of available personnel [ CITATION USD141 \l 1033 ]. VFDs are not recommended for pumps with high static head or pumps that operate for extended periods under low flow conditions [CITATION NSW171 \l 1033 ]. Therefore, VFDs are not suited for pumps that pull water from deep groundwater wells, and are best fitted for smaller surface/booster and fertilizer pumps. Figure 11 summarizes the operational characteristics of a pump with a VFD under different speeds. Note that there is no static head present in Figure 4, only dynamic head . As discussed earlier, groundwater pumps can be easily coupled with water storage and be able to shift their operations to off peak hours. Therefore, VFDs with their drawbacks for high static head systems are not the best fit for groundwater pumps. However, VFDs would be ideal for tapping into the DR potential that booster and surface pumps can provide. Given that booster pumps need to maintain a minimum pressure on the irrigation system, VFDs can allow modulation of their power and allow such systems to provide DR services to the electric grid while meeting the operational requirements of a farm’s irrigation system. According to Figure 4, a low static head pump can reduce its power demand by a third without significant efficiency losses if operated correctly.Over 57,000 farm businesses and other farms were engaged in producing renewable energy such as solar, wind, and geothermal in 2012, more than twice as many as in 2007 . Solar energy production is the most prevalent from on farm renewable energy, with an estimated 82% of farms with renewable energy generation reporting solar electricity generation capacity . With dropping prices of solar energy, agricultural industry can benefit from dual land use for energy production. Solar panels installed on an irrigation ponds can reduce evaporative losses, and solar arrays installed elsewhere on a farm can provide shading for the livestock or the farming equipment .

On farm renewable energy production can also protect farms from volatile energy prices. This trend provides an added incentive for farmers to get a better handle on the timing of their energy use, and restructure their operations to utilize larger amounts of renewable energy such as wind and solar . Much of the infrastructure and technology that can be used for AutoDR enablement, can be used for helping farms in maximizing the use of the onsite generated renewable energy. The framework put forward in this paper also helps pave the path for policy development as farms transition from being net energy consumers to net energy generators. A high renewable penetration grid requires flexible loads in order to maintain its stability. Agricultural loads, with their large magnitude can provide that flexibility as energy markets move into a future of increasingly distributed and intermittent renewable generation. However, several on farm constraints, as well as lack of appropriate market mechanisms limit farms from taking advantage of more flexible energy and water use strategies that could benefit the grower, utility, and the grid. Agricultural demand management programs have proven to be unsuccessful in facilitating the needs of the farm and helping the utilities manage their demand and reduce cost. This indicates that current programs and tariffs do not adequately account for the needs of the grid and constraints that exist on farms. New technologies and market based approaches are needed to give utilities greater flexibility and their agricultural customers greater incentives to balance the grid and meet the high penetration of renewable sources in the coming decades. To address these barriers for DR adoption, researchers and Agricultural Technology  companies have focused on topics such as scientific irrigation scheduling, real time irrigation prediction using sensor data, and remote scheduling of operations. In the meantime, utilities have done very little to tailor their DR programs to the needs of agricultural operations. A common misconception within the AgTech industry is that technology alone will inherently bring all the benefits. However, technology can lead to more complications if it is not coupled with improved management and training.

In recent years, an abundance of AgTech companies , has led to a surge of promising technologies but most lack scalability and impact on the field. For example, various models of water efficiency and environmental benefits have been developed, yet they are under utilized in irrigation scheduling; at most, they help retrospectively to evaluate seasonal approaches . Another example is of soil moisture sensors being ubiquitous on the market but are not easy to handle, lack reliability, and fail to provide adequate spatial data. The same situation applies to technologies geared toward managing energy and electricity demand on farms. Several years of agricultural DR research has identified that the DR and pathways through which a farm can be approved and enabled for DR, participate in DR events, and receive compensation are complex. Most farms lack the in house expertise for going through the entire process without the help of external consultants. Without an energy or sustainability manager, it is very challenging and intimidating for farms to even begin to approach DR enablement – unless they put all their faith in a utility or aggregator in spite of their own lack of understanding. The research for facilitating higher uptake of agricultural DR has been segmented by keeping farmers, grid operators, and utilities in silos with little thought to having them talk and understand each other’s needs. Moreover, much of AgTech sector’s focus has been on yield increase and crop quality improvement and little attention has gone towards other operational aspects of the farm including irrigation energy and water management. Ultimately,arándanos azules cultivo irrigated agriculture will need to adopt a new management paradigm based on an economic objective which not only includes yield but also takes into account water and energy . The framework put forward in this paper is unique as no similar farm to grid analysis framework has been identified in the extensive literature search in the field of agricultural water and energy. The discussion put forward in this paper can be summarized in a diagram similar to what is presented in Figure 13. With the information provided in previous sections, one should be able to connect various on farm electricity consuming equipment to the appropriate grid need using available market mechanisms. This framework will allow identification of missing market mechanisms for tapping into agricultural DR potential or can shed light on technology gaps that can facilities higher DR participation of agricultural farms. Figure 13 is intended to serve as a starting point for addressing the knowledge gap that hinders farms to provide valuable DR services to the grid and benefit from untapped revenue streams. The future work should be focused on data collection that will allow better mapping of farm equipment to various grid needs through existing mechanism or developing new ones. Even though this paper will not provide an end to end solution for DR enablement at farms, but it paves the way for widespread DR participation for all significant electricity users on farms. Figure 12 illustrates a hypothetical application of the proposed framework. In the example below, actual farm load profiles are disaggregated into various end uses . Based on the information collected regarding each end use , the relevant component of the load profile can then be mapped to the appropriate grid need based on its characteristics .The federal government’s under count of nonfatal occupational injuries and illnesses for all industries combined has received considerable research and popular press attention. A US General Accounting Office report addressed under counting and suggested remedies for all industries combined. This study extends previous research by focusing on agriculture, an industry that merits special attention for several reasons.

First, although estimates vary, agriculture employs roughly 2 to 4 million people, and includes the highest share of self-employed persons in any industry. Second, agriculture is among the most hazardous industries, especially for the self-employed. Third, agriculture employs many undocumented workers; for example, the most recent analysis from the National Agricultural Workers Survey estimated 53% of all hired crop workers were undocumented. Contentious debate surrounds whether undocumented workers should be granted citizenship and the impact this may have on workers’ subsequent use of Medicaid and workers’ compensation. Fourth, many farm workers are migrants; the NAWS estimated 42% of crop workers annually traveled 75+ miles to obtain jobs. Fifth, and most importantly, agriculture poses the greatest challenge of any industry for generating estimates of under counting because of the seasonal nature of employment, and predominance of small, family-run operations. We measured the injury and illness under count as the difference between estimates from the Bureau of Labor Statistics ’s Survey of Occupational Injuries and Illnesses and our own estimates. Unlike the SOII, we accounted for the self-employed and workers on small farms as well as willful and negligent under reporting by both employees and employers. We believe our estimates are conservative, in part because we use the same criteria as the BLS to qualify a case as an occupational injury or illness. We do not include, for example, estimates of job-related cancers, COPD, and circulatory disease that far exceed those recognized by the SOII. The under count has institutional and behavioral causes. Institutional causes pertain to deliberate reasons for excluding persons. Two of these institutional causes are the exclusions of self-employed farmers on all farms and workers on farms with <11 employees from the SOII. A third institutional cause is the government’s under count of employment of farm workers in virtually all government data sets. This employment under count is widely recognized owing to the fluid and part-time nature of farm work. BLS readily acknowledges the employment under count and estimates its magnitude in supplements to the Quarterly Census of Employment and Wages. There are two behavioral causes: negligence and willful under reporting. Despite the under count, the SOII is widely cited by researchers and journalists, in part, because it has been providing the only annual national estimates of nonfatal workplace injuries and illnesses for 40 years. There are three additional data sets with relevant information, but none as comprehensive as the SOII. The National Health Interview Survey provides information on injuries, but not illnesses, nor estimates within industries. The Census of Fatal Occupational Injuries provides information within agriculture, but only for injury fatalities. The National Agricultural Workers Survey contains data on injuries but only for crop, not animal farms.The 1970 Occupational Safety and Health Act requires very high percentages of firms to record qualifying work-related injuries and illnesses, i.e., those associated with death, loss of consciousness, lost or restricted work days, or medical treatment beyond first aid.